If you love iPhone, you'll love Apple Card. It's the credit card designed for iPhone. It gives you unlimited daily cash back that can earn four point four zero percent annual percentage yield. When you open a high Yield savings account through Apple Card, apply for Applecard in the wallet app subject to credit approval. Savings is available to Apple Card owners subject to eligibility. Apple Card and Savings by Goldman Sachs Bank USA, Salt Lake City Branch Member FDIC terms and more at applecard dot com. When you pop a piece of cheese into your mouth, you're probably not thinking about the environmental impact. But the people in the dairy industry are. That's why they're working hard every day to find new ways to reduce waste, conserve natural resources, and drive down greenhouse gas emissions. How is US Dairy tackling greenhouse gases? Many farms use anaerobic digesters to turn the methane from manure into renewable energy that can power farms, towns, and electric cars. Visit us Dairy dot COM's Last Sustainability to learn more.

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Here's a little secret. Most smartphone deals aren't that exciting. To be honest, they're barely worth mentioning. But then there's AT and T and their best deals. Those are quite exciting.

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Isaac Newton was very clearly a smart guy. He made huge leaps and understanding of optics and gravity and calculus, But one of the biggest mental steps he took was applying the laws that we have down here on Earth to what's going on up there in space. His biggest idea was probably that there should only be one idea, one set of physical laws, but that it should cover everything. And here we sit on a tiny isolated rock in space, trying to make rules that explain the whole universe, only able to see a tiny little bit of it and study with our hands and our tools an even smaller bit. It's sort of like visiting the zoo and only seeing the insect exhibit, but then making laws that are supposed to describe how elephants and amphibians work. So ask yourself, how likely is it that our ideas are actually universal? Hi? I'm Daniel, I'm a particle physicist, and I have an infinite list of questions about our probably infinite universe. And Welcome to the podcast Daniel and Jorge Explain the Universe, a production of iHeartRadio. We talk about things happening far far away, and we talk about things happening under your feet. We ask questions about the very beginning of time. We ask questions about the very nature of time and the end of time. We ask questions about the entire universe. Because we think that curiosity and asking questions is universal. We think everybody out there has questions, and everybody deserves to have their questions explored, if not answered, because not every question has an answer to it so far. But questions really are at the heart of science, and that's why on today's program, while my friend collaborator and co host Jorge can't be here today, I'm going to take the opportunity to gather up a bunch of questions asked from listeners and try to answer them. We're always asking people please send us your questions. If there's something you don't understand about the universe, something you've read and didn't quite follow, something you've thought through that didn't quite make sense to you, please send it to us because we cherish those questions. Those questions are our opportunity to help people understand what we do and what we don't know about the universe. And remember that everybody out there who was asking questions is basically an armchair physicist. If you are trying to wrap your mind around the universe, you're trying to make one holistic sense of understanding of how things work. If you've read something somewhere and you're trying to make it agree with something else you used to think, or something you read somewhere else or something your friend told you that's doing physics. You are trying to unify your understanding. You're saying, I need to have one set of ideas that describes the entire universe, that explains everything. Now, of course, we don't know if it's possible to describe the entire universe using one set of laws. We don't know if it's possible for humans to do it, or maybe take some super alien intelligence or some artificial intelligence with super incredible powers. But that doesn't stop us from trying, because it's our dream that we could encapsulate the entire workings of the universe somehow inside the puny human mind. So please, if we haven't answered a question that's in your mind, send it to us to questions at Danielandjorge dot com. We answer all of our emails and sometimes we put those questions here on the podcast. But if you don't like writing emails or you don't want to engage with us on Twitter, we have other ways to get your questions answered. You can check out daniels public office hours, look at the website for the podcast, or go to sites dot UCI dot edu slash Daniel. You'll see a link there for when Daniel has public office hours, he hangs out on Zoom and answers questions about physics and life in the universe and everything from people like you, people who have thought about stuff and have a nagging little question that they can't find the answer to using Google and they just have to know how it works, all right, And today on the podcast will be answering questions from listeners from all over the world. Our first question comes to us from Germany. I have a question concerning doc energy. Does it violate the law of energy conservation? It seems to come out of nothing and getting bigger and bigger. Thanks a lot, all right, Thank you andres from Germany. This is a beautiful example of what I was just talking about about applying our ideas about how things work in the universe and taking them to the extreme and saying does this really work everywhere? Is this a universal law? Is there some part of the universe that seemed to break this rule which would make it not universal? And one of the most fundamental things we thought we understood about the universe was this idea of energy conservation. Of course, one hundred years ago we thought other things were conserved like mass. We thought that stuff was conserved, that you could move it around, you could switch it up, you could rearrange it like logo bricks, but you couldn't create or destroy mass. Now, of course we know that's not true. And the lesson we learned from that, from the lack of mass conservation, is that mass is not a fundamental element of the universe. It can be created, it can be destroyed. You can have more mass, you can have less mass. It's not something which we should consider sort of on the list of fundamental descriptors of the universe. And that's important because what we're doing with physics is trying to drill down to the most fundamental, the simplest description, because we imagine if one day we are looking at a list of the fundamental elements of the universe, the things that define the universe and completely explain the universe, that we will somehow be revealing the nature of the universe. So we don't want anything on that list which isn't fundamental. You don't want that list to have like strings and energy and then ice cream, right because ice cream can be described by all the other elements already on the list. So we want to strip it down to a sort of most minimal set of rules, most minimal set of things you need to describe the universe. Having left our list of things that describe how the universe works, tells us something about what the universe isn't. It isn't a place that cares so much about mass. However, energy seems to have retained its exalted stature as a quantity which is concerned. And you know what is energy conservation anyway? Energy conservation is the statement that you can calculate this thing about nature. You add up all the energy in a system, all the ways that things can move or wiggle or store energy, and then you let a bunch of stuff happen. Things collide, things explode, things slash around, whatever, and you add up all the energy again and it should be the same. So it's sort of a statement that energy is fundamental to the universe. You can move it around, that you can change it from one thing to another, but you can't get rid of it. That it's inherent, that it's fundamental, that it's a deep part of what makes the universe the universe. So if energy is not concerned, then that tells you what it tells you that maybe energy isn't actually important to the universe. Maybe energy isn't on that list of fundamental elements we think are needed to define and describe the universe. So Andreas is doing exactly what a physicist should be doing, thinking about ways energy conservation might be violated. We know, for example, that if you roll a boulder up a hill, you're spending energy in your muscles, and that energy then goes into the position of the boulder. Its gravitational location is more distant from the Earth, and if you let go of the boulder and run it back down the hill, the energy goes from that potential energy of the boulder into its motion, into its kinetic energy. So we have lots of examples of where energy is conserved, and people probably expect to hear that energy is conserved everywhere in the universe, and there's some way you can do the calculation to figure out that energy is actually conserved in the case of dark energy, So what is he talking about. Remember that dark energy is not something that's very well understood. It's not a theoretically well formulated idea. It's more an observation. It's an observation that the universe is expanding, and that that expansion is accelerating. So we look out into the universe and we see that the universe is expanding, and not only are things moving away from us, but the speed at which they are moving away from us is increasing. You might expect the opposite to be happening, and in fact, physicists expected the opposite to be happening for a long time. That things were moving away from us, but that speed might be decreasing as gravity very slowly pulls on things and tugs them back together after the Big Bang. What we actually found about twenty twenty five years ago now is that things are moving away from us faster and faster, and we don't have an explanation for why this is. All we have is the observation that it is happening. There are a few sort of proto explanations. There are ideas for what might describe it, but none of those ideas really work so far. One of those ideas is that there is energy in empty space, that all of space has energy in it. For example, the Higgs Boson field is a quantum field that's in all of space, and even when it's at its most relaxed, at its lowest level, it doesn't have zero energy in it. That means that when you create a piece of space, you're creating a Higgs Boson field that has energy in it. And this is what Andreas is talking about, that dark energy creates more space because it's not just moving things through space, creating new space between galaxies. It's stretching that space. It's making new space. And when you make new space, it comes with new energy. So it seems an awful law like dark energy is in fact violating conservation of energy because as you make more space, you are increasing the total volume of the universe. And if every cubic meter of space has a certain energy, then by increasing the volume of space, you're increasing the total energy in the universe. How does that not violate conservation of energy, Well, in fact it does, and z energy conservation is not guaranteed in our universe. And this is one example. As space expands, the energy increases because you get more dark energy, which means overall more energy. There's also another example, which is that energy can decrease when space expands. If you have a photon flying through space, for example from the cosmic microwave background radio, then what happens when space expands. When space stretches, well, that photon gets red shifted. Its wavelength gets longer because space has gotten stretched. Right, Imagine you draw a wiggle on a sheet of paper and then you stretch that paper, the wavelength gets longer. But for photons, the energy and the wavelength are very closely connected. One defines the other. Higher energy photons are those with shorter wavelengths, and so if you stretch the wavelength of a photon, then you decrease its energy. Where does that energy go. It doesn't go anywhere, It just goes away. So we have two examples of the violation of the conservation of energy, both coming from space expanding. And that's the clue. That's the clue that tells us why energy might not be conserved. And most of the conservation laws in physics, most of the things that are conserved that are not changed when you let things bang around and smash into each other, come from some kind of symmetry. This is this very deep result in physics called Noether's theorem from Emily Norther who developed it more than one hundred years ago, and she discovered that every time you have a symmetry, like every time you can take space and rotate it and still get the same laws of physics, or move your coordinate system over by ten kilometers and still expect the same law of physics, or fast forward things by one hundred years and still expect the same laws of physics. Every time you can apply some sort of translation or rotation to the universe and not see any change in the law of physics. That's a symmetry, and every symmetry has some kind of conservation law that comes from it. So, for example, the fact that space is the same everywhere, that the laws of physics apply here and somewhere else, that gives you the law of conservation of momentum, and the fact that you can rotate space, that there's no preferred direction, that physics should work the same in every direction. That's why we have conservation of angular momentum, and it's the symmetry of the universe with respect to time is what gives us conservation of energy. The fact that it seems like the universe should work the same now as it does in one hundred years and a thousand years ago is what gives us conservation of energy. But that only works if we expect the same rules to apply now and in one hundred years and in a thousand years. That only works if space is essentially static, if it's not changing, if space is the same now and in one hundred years and a thousand years ago. But we know that it's not because we know that space is expanding. So conservation of energy is something we expect to apply in a static universe where space is not changing. In our universe, however, space is expanding, and it's expanding quite rapidly. Expansion is not a small thing in our universe. Seventy percent of the energy budget of the universe goes towards the expansion of space time, so when space is expanding, energy is not conserved. Now, we did a whole podcast episode about this conservation of energy, and there is one way that you can sort of rig up a calculation in which you get negative energy from gravity that might account for some of this, but most cosmologists think it's sort of a band aid and theoretically doesn't hold together. And you're interested in more details and not check out our whole podcast episode about conservation of energy. But congrats to you Andreas for figuring this out. For applying your understanding of physics to crazy scenarios far beyond your living room and coming up with a contradiction. And those contradictions are what lead to questions, and those questions are what lead us to deeper understandings about the universe. So keep asking questions. Thanks very much for sending that in all right, I have more questions from listeners I want to get to, but first, let's take a quick break. With big wireless providers, what you see is never what you get. Somewhere between the store and your first month's bill, the price you thought you were paying magically skyrockets. With mint Mobile, you'll never have to worry about gotcha's ever again. When Mint Mobile says fifteen dollars a month for a three month plan, they really mean it. 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Isaac Newton was very clearly a smart guy. He made huge leaps and understanding of optics and gravity and calculus, But one of the biggest mental steps he took was applying the laws that we have down here on Earth to what's going on up there in space. His biggest idea was probably that there should only be one idea, one set of physical laws, but that it should cover everything. And here we sit on a tiny isolated rock in space, trying to make rules that explain the whole universe, only able to see a tiny little bit of it and study with our hands and our tools an even smaller bit. It's sort of like visiting the zoo and only seeing the insect exhibit, but then making laws that are supposed to describe how elephants and amphibians work. So ask yourself, how likely is it that our ideas are actually universal? Hi? I'm Daniel, I'm a particle physicist, and I have an infinite list of questions about our probably infinite universe. And Welcome to the podcast Daniel and Jorge Explain the Universe, a production of iHeartRadio. We talk about things happening far far away, and we talk about things happening under your feet. We ask questions about the very beginning of time. We ask questions about the very nature of time and the end of time. We ask questions about the entire universe. Because we think that curiosity and asking questions is universal. We think everybody out there has questions, and everybody deserves to have their questions explored, if not answered, because not every question has an answer to it so far. But questions really are at the heart of science, and that's why on today's program, while my friend collaborator and co host Jorge can't be here today, I'm going to take the opportunity to gather up a bunch of questions asked from listeners and try to answer them. We're always asking people please send us your questions. If there's something you don't understand about the universe, something you've read and didn't quite follow, something you've thought through that didn't quite make sense to you, please send it to us because we cherish those questions. Those questions are our opportunity to help people understand what we do and what we don't know about the universe. And remember that everybody out there who was asking questions is basically an armchair physicist. If you are trying to wrap your mind around the universe, you're trying to make one holistic sense of understanding of how things work. If you've read something somewhere and you're trying to make it agree with something else you used to think, or something you read somewhere else or something your friend told you that's doing physics. You are trying to unify your understanding. You're saying, I need to have one set of ideas that describes the entire universe, that explains everything. Now, of course, we don't know if it's possible to describe the entire universe using one set of laws. We don't know if it's possible for humans to do it, or maybe take some super alien intelligence or some artificial intelligence with super incredible powers. But that doesn't stop us from trying, because it's our dream that we could encapsulate the entire workings of the universe somehow inside the puny human mind. So please, if we haven't answered a question that's in your mind, send it to us to questions at Danielandjorge dot com. We answer all of our emails and sometimes we put those questions here on the podcast. But if you don't like writing emails or you don't want to engage with us on Twitter, we have other ways to get your questions answered. You can check out daniels public office hours, look at the website for the podcast, or go to sites dot UCI dot edu slash Daniel. You'll see a link there for when Daniel has public office hours, he hangs out on Zoom and answers questions about physics and life in the universe and everything from people like you, people who have thought about stuff and have a nagging little question that they can't find the answer to using Google and they just have to know how it works, all right, And today on the podcast will be answering questions from listeners from all over the world. Our first question comes to us from Germany. I have a question concerning doc energy. Does it violate the law of energy conservation? It seems to come out of nothing and getting bigger and bigger. Thanks a lot, all right, Thank you andres from Germany. This is a beautiful example of what I was just talking about about applying our ideas about how things work in the universe and taking them to the extreme and saying does this really work everywhere? Is this a universal law? Is there some part of the universe that seemed to break this rule which would make it not universal? And one of the most fundamental things we thought we understood about the universe was this idea of energy conservation. Of course, one hundred years ago we thought other things were conserved like mass. We thought that stuff was conserved, that you could move it around, you could switch it up, you could rearrange it like logo bricks, but you couldn't create or destroy mass. Now, of course we know that's not true. And the lesson we learned from that, from the lack of mass conservation, is that mass is not a fundamental element of the universe. It can be created, it can be destroyed. You can have more mass, you can have less mass. It's not something which we should consider sort of on the list of fundamental descriptors of the universe. And that's important because what we're doing with physics is trying to drill down to the most fundamental, the simplest description, because we imagine if one day we are looking at a list of the fundamental elements of the universe, the things that define the universe and completely explain the universe, that we will somehow be revealing the nature of the universe. So we don't want anything on that list which isn't fundamental. You don't want that list to have like strings and energy and then ice cream, right because ice cream can be described by all the other elements already on the list. So we want to strip it down to a sort of most minimal set of rules, most minimal set of things you need to describe the universe. Having left our list of things that describe how the universe works, tells us something about what the universe isn't. It isn't a place that cares so much about mass. However, energy seems to have retained its exalted stature as a quantity which is concerned. And you know what is energy conservation anyway? Energy conservation is the statement that you can calculate this thing about nature. You add up all the energy in a system, all the ways that things can move or wiggle or store energy, and then you let a bunch of stuff happen. Things collide, things explode, things slash around, whatever, and you add up all the energy again and it should be the same. So it's sort of a statement that energy is fundamental to the universe. You can move it around, that you can change it from one thing to another, but you can't get rid of it. That it's inherent, that it's fundamental, that it's a deep part of what makes the universe the universe. So if energy is not concerned, then that tells you what it tells you that maybe energy isn't actually important to the universe. Maybe energy isn't on that list of fundamental elements we think are needed to define and describe the universe. So Andreas is doing exactly what a physicist should be doing, thinking about ways energy conservation might be violated. We know, for example, that if you roll a boulder up a hill, you're spending energy in your muscles, and that energy then goes into the position of the boulder. Its gravitational location is more distant from the Earth, and if you let go of the boulder and run it back down the hill, the energy goes from that potential energy of the boulder into its motion, into its kinetic energy. So we have lots of examples of where energy is conserved, and people probably expect to hear that energy is conserved everywhere in the universe, and there's some way you can do the calculation to figure out that energy is actually conserved in the case of dark energy, So what is he talking about. Remember that dark energy is not something that's very well understood. It's not a theoretically well formulated idea. It's more an observation. It's an observation that the universe is expanding, and that that expansion is accelerating. So we look out into the universe and we see that the universe is expanding, and not only are things moving away from us, but the speed at which they are moving away from us is increasing. You might expect the opposite to be happening, and in fact, physicists expected the opposite to be happening for a long time. That things were moving away from us, but that speed might be decreasing as gravity very slowly pulls on things and tugs them back together after the Big Bang. What we actually found about twenty twenty five years ago now is that things are moving away from us faster and faster, and we don't have an explanation for why this is. All we have is the observation that it is happening. There are a few sort of proto explanations. There are ideas for what might describe it, but none of those ideas really work so far. One of those ideas is that there is energy in empty space, that all of space has energy in it. For example, the Higgs Boson field is a quantum field that's in all of space, and even when it's at its most relaxed, at its lowest level, it doesn't have zero energy in it. That means that when you create a piece of space, you're creating a Higgs Boson field that has energy in it. And this is what Andreas is talking about, that dark energy creates more space because it's not just moving things through space, creating new space between galaxies. It's stretching that space. It's making new space. And when you make new space, it comes with new energy. So it seems an awful law like dark energy is in fact violating conservation of energy because as you make more space, you are increasing the total volume of the universe. And if every cubic meter of space has a certain energy, then by increasing the volume of space, you're increasing the total energy in the universe. How does that not violate conservation of energy, Well, in fact it does, and z energy conservation is not guaranteed in our universe. And this is one example. As space expands, the energy increases because you get more dark energy, which means overall more energy. There's also another example, which is that energy can decrease when space expands. If you have a photon flying through space, for example from the cosmic microwave background radio, then what happens when space expands. When space stretches, well, that photon gets red shifted. Its wavelength gets longer because space has gotten stretched. Right, Imagine you draw a wiggle on a sheet of paper and then you stretch that paper, the wavelength gets longer. But for photons, the energy and the wavelength are very closely connected. One defines the other. Higher energy photons are those with shorter wavelengths, and so if you stretch the wavelength of a photon, then you decrease its energy. Where does that energy go. It doesn't go anywhere, It just goes away. So we have two examples of the violation of the conservation of energy, both coming from space expanding. And that's the clue. That's the clue that tells us why energy might not be conserved. And most of the conservation laws in physics, most of the things that are conserved that are not changed when you let things bang around and smash into each other, come from some kind of symmetry. This is this very deep result in physics called Noether's theorem from Emily Norther who developed it more than one hundred years ago, and she discovered that every time you have a symmetry, like every time you can take space and rotate it and still get the same laws of physics, or move your coordinate system over by ten kilometers and still expect the same law of physics, or fast forward things by one hundred years and still expect the same laws of physics. Every time you can apply some sort of translation or rotation to the universe and not see any change in the law of physics. That's a symmetry, and every symmetry has some kind of conservation law that comes from it. So, for example, the fact that space is the same everywhere, that the laws of physics apply here and somewhere else, that gives you the law of conservation of momentum, and the fact that you can rotate space, that there's no preferred direction, that physics should work the same in every direction. That's why we have conservation of angular momentum, and it's the symmetry of the universe with respect to time is what gives us conservation of energy. The fact that it seems like the universe should work the same now as it does in one hundred years and a thousand years ago is what gives us conservation of energy. But that only works if we expect the same rules to apply now and in one hundred years and in a thousand years. That only works if space is essentially static, if it's not changing, if space is the same now and in one hundred years and a thousand years ago. But we know that it's not because we know that space is expanding. So conservation of energy is something we expect to apply in a static universe where space is not changing. In our universe, however, space is expanding, and it's expanding quite rapidly. Expansion is not a small thing in our universe. Seventy percent of the energy budget of the universe goes towards the expansion of space time, so when space is expanding, energy is not conserved. Now, we did a whole podcast episode about this conservation of energy, and there is one way that you can sort of rig up a calculation in which you get negative energy from gravity that might account for some of this, but most cosmologists think it's sort of a band aid and theoretically doesn't hold together. And you're interested in more details and not check out our whole podcast episode about conservation of energy. But congrats to you Andreas for figuring this out. For applying your understanding of physics to crazy scenarios far beyond your living room and coming up with a contradiction. And those contradictions are what lead to questions, and those questions are what lead us to deeper understandings about the universe. So keep asking questions. Thanks very much for sending that in all right, I have more questions from listeners I want to get to, but first, let's take a quick break. With big wireless providers, what you see is never what you get. Somewhere between the store and your first month's bill, the price you thought you were paying magically skyrockets. With mint Mobile, you'll never have to worry about gotcha's ever again. When Mint Mobile says fifteen dollars a month for a three month plan, they really mean it. I've used mint Mobile and the call quality is always so crisp and so clear I can recommend it to you. So say bye bye to your overpriced wireless plans, jaw dropping monthly bills and unexpected overages. You can use your own phone with any mint Mobile plan and bring your phone number along with your existing contacts. So dit your overpriced wireless with mint Mobiles deal and get three months a premium wireless service for fifteen bucks a month. To get this new customer offer and your new three month premium wireless plan for just fifteen bucks a month, go to mintmobile dot com slash universe. That's mintmobile dot com slash universe. Cut your wireless bill to fifteen bucks a month. At mintmobile dot com slash universe. Forty five dollars upfront payment required equivalent to fifteen dollars per month New customers on first three month plan only speeds slower about forty gigabytes on unlimited plan. Additional taxi spees and restrictions apply. See mint mobile for details.

AI might be the most important new computer technology ever. It's storming every end of and literally billions of dollars are being invested, so buckle up. The problem is that AI needs a lot of speed and processing power. So how do you compete without cost spiraling out of control. It's time to upgrade to the next generation of the cloud. Oracle Cloud Infrastructure or OCI. OCI is a single platform for your infrastructure, database, application development, and AI needs. OCI has four to eight times the bandwidth of other clouds, offers one consistent price instead of variable regional pricing, and of course nobody does data better than Oracle, So now you can train your AI models at twice the speed and less than half the cost of other clouds. If you want to do more and spend less, like Uber eight by eight and Data Bricks Mosaic, take a free test drive of OCI at Oracle dot com slash strategic. That's Oracle dot com slash Strategic. Oracle dot com slash Strategic.

AI might be the most important new computer technology ever. It's storming every end of and literally billions of dollars are being invested, so buckle up. The problem is that AI needs a lot of speed and processing power. So how do you compete without cost spiraling out of control. It's time to upgrade to the next generation of the cloud. Oracle Cloud Infrastructure or OCI. OCI is a single platform for your infrastructure, database, application development, and AI needs. OCI has four to eight times the bandwidth of other clouds, offers one consistent price instead of variable regional pricing, and of course nobody does data better than Oracle, So now you can train your AI models at twice the speed and less than half the cost of other clouds. If you want to do more and spend less, like Uber eight by eight and Data Bricks Mosaic, take a free test drive of OCI at Oracle dot com slash strategic. That's Oracle dot com slash Strategic. Oracle dot com slash Strategic.

If you love iPhone, you'll love Apple Card. It's the credit card designed for iPhone. It gives you unlimited daily cash back that can earn four point four zero percent annual percentage yield. When you open a high Yield savings account through Apple Card, apply for Apple Card in the wallet app, subject to credit approval. Savings is available to Apple Card owners subject to eligibility. Apple Card and Savings by Goldman Sachs Bank USA Salt Lake City Branch Member FDIC terms and more at applecard dot com. All right, we're back, and this is Danielle and I'm here today on my own answering questions from listeners. I love when people write to us. They send us amazing questions, things that they have been thinking about the universe and that they can't figure out via Google, and they don't happen to know a physicist they can ask these questions of, so they send them to us. And I have a bit of an embarrassing backlog of questions from listeners that I really want to get to. And so while Jorge isn't here, I'm going to apply through a bunch of these and try to catch up to our backlog. So thanks very much to everybody who's sent in questions. Here's the next question we're going to answer today.

If you love iPhone, you'll love Apple Card. It's the credit card designed for iPhone. It gives you unlimited daily cash back that can earn four point four zero percent annual percentage yield. When you open a high Yield savings account through Apple Card, apply for Apple Card in the wallet app, subject to credit approval. Savings is available to Apple Card owners subject to eligibility. Apple Card and Savings by Goldman Sachs Bank USA Salt Lake City Branch Member FDIC terms and more at applecard dot com. All right, we're back, and this is Danielle and I'm here today on my own answering questions from listeners. I love when people write to us. They send us amazing questions, things that they have been thinking about the universe and that they can't figure out via Google, and they don't happen to know a physicist they can ask these questions of, so they send them to us. And I have a bit of an embarrassing backlog of questions from listeners that I really want to get to. And so while Jorge isn't here, I'm going to apply through a bunch of these and try to catch up to our backlog. So thanks very much to everybody who's sent in questions. Here's the next question we're going to answer today.

Hey guys, this is Jeff from Los Angeles. My question relates to the period of inflation after the Big Bang. I know you said the universe expanded by a factor of ten to the thirty in a small amount of time of ten to the minus thirty. How do you explain that if nothing can travel faster than the speed of light. I also want to know if the edges of the universe were expanding at this crazy fast speed, and it was expanding through nothing, then what's slowing it down? Why isn't the universe still expanding at that crazy rate of inflation? I look forward to the answer.

Hey guys, this is Jeff from Los Angeles. My question relates to the period of inflation after the Big Bang. I know you said the universe expanded by a factor of ten to the thirty in a small amount of time of ten to the minus thirty. How do you explain that if nothing can travel faster than the speed of light. I also want to know if the edges of the universe were expanding at this crazy fast speed, and it was expanding through nothing, then what's slowing it down? Why isn't the universe still expanding at that crazy rate of inflation? I look forward to the answer.

Thanks a lot, all right, Jeff from La who's basically an amateur cosmologist. Thank you for thinking deeply about the universe and for trying to reconcile what you've heard about the early days of the universe with what you understand about how the universe works. Again, that's exactly what doing physics means, so let's get to it. The first part of your question was if the universe expanded by a factor of ten to the thirty and ten to the minus thirty questions, how is that possible? Given that we know that there's a very hard limit on how fast things can move through space, which is the speed of light. It's a great question. Another way to think about this question is how did the universe get so big? I mean, the universe is about fourteen billion years old, but the size of the observable universe, the distance to the furthest things that we can see, you might expect to be fourteen billion years times the speed of light, which would be fourteen billion light years, but it's not. It's much much further than that. We can see things that are about forty five billion light years away, So the size of the observable universe is about ninety billion light years wide. How is that possible. How is it possible to see things which are further away then the speed of light times the age of the universe. How did that stuff get there so far? How did the universe expand faster than the speed of light? So it's a wonderful question. And the key concept you need to know to understand this is that there's a difference between moving through space and expansion of space. So moving through space is the kind of thing you're familiar with. You move through space every day when you get out of your bed and you go for a glass of water in the middle of the night, and you are moving through space. When you throw a baseball really really fast. When you get on your spaceship and you try to travel to a nearby star, you are moving through space. When you turn on your flashlight and you shine it at the moon, you are sending photons through space to the moon. And there is in fact, a very hard limit on the speed at which things can move through space, and that's the speed of light. In a vacuum, nothing, no information at all, can move through space faster than the speed of light. That includes neutrinos, that includes everything that include quantum information. It's a very tough rule, and breaking it would undermines special relativity, which we're pretty sure as an accurate description of space time in our universe. All right, so that's moving through space, but that's different from the expansion of space. The expansion of space means stretching space itself. So imagine, for example, you are one meter apart from your friend. You have a meter stick, and you measure exactly how far apart you are. You could take a step back. That would be moving through space. But you could also expand the space between you. You could take the very universe and stretch it so that now you guys are two meters apart without having moved through space at all. Right, Remember, space is not just the backdrop on which things happen. It's not the stage on which the acts of the universe are played out on. It's a dynamical thing. It's stretchy, it's like goo. It responds to the presence of mass and energy. It bends, it twists, it can expand, and it tells things how to move. So space is really part of the universe. It's not just like some fuzzy abstract concept, some set of glowing axes in our mind. That we just impose on the universe to try to make sense of it. Space really can do a bunch of weird things. You already know this because you know that gravity is not just a force, it's actually the curving of space. Right. The reason that the Earth goes around the Sun is not because gravity is a force which is tugging on it, but because the presence of the Sun changes the shape of space in its vicinity, so that an object moving in a straight up inertial path will move in a circle around the Sun. That's because space can bend and twist, changing the relative distances between things. So, for example, a photon a beam of light always takes the shortest path between two things. But the shortest path between two things isn't always what you imagine to be a straight line, because the shape of space can be complicated between two points the same way an airplane going from la to London takes the Great Circle route, right, which seems like a curve, is actually the shortest distance between two places on a curved surface, which is why gravity can influence even things that don't have mass. All right, So that tells us that space can do things, and it can stretch and it can expand. And so that's exactly what happened in the very early universe. It wasn't an explosion like a tiny dot of stuff and then everything exploded out from the center. Instead, it was an expansion of space itself. Huge amounts of new space were made everywhere all over the universe simultaneously. So that doesn't make it easier to understand. In fact, it makes it even more bind boggling that this happened, That every unit of space was blown up by a factor ten to the thirty in ten to the minus thirty seconds. It's an incredible moment in the history of the universe. It's an incredible idea to even have in your mind. Imagine coming up with this Bonker's notion and then realizing that actually it's the story that makes the most sense in the universe. And you might ask, well, how do we know, How do we know that the universe expanded in this way, that it didn't just explode from a tiny dot and spread out through the universe. Well, answer number one is that it would be impossible. As you say, it's not possible for things to travel that far in that short distance because of the limitation of the speed of light. It's against the rules. The only way to get things that far apart in that short amount of time is to create space between them, is to expand the space between everything. But it's more than that, because explosions and expansion look different. Explosions are like a bomb. You push everything out from one central location and send it flying in every direction, and if there is an explosion, you could look at the direction things are flying, you could track them backwards, and you could point back to the center. Right. If you come upon an explosion, you can look at the path of the debris and you can figure out where the bomb was. That's not true for an expansion. An expansion is more like a loaf of bread rising in the oven, where everything is growing at every point simultaneously, assuming you're not a terrible baker, right, and that your loaf is expanding smoothly. And that's what we see when we look out into the universe. We see these galaxies and they are rushing away from us. They are moving away from us, and they're moving away from us faster and faster every year. So either we are at the exact center of the universe by some incredible cosmic coincidence. There was an explosion and we happen to be right at the center of it. Or it looks this way because it's an expansion, and it would look this way at any point in the universe. See, the way an expansion looks is that it always looks like you're at the center of it, no matter where you are. And a loaf of bread, if you look around you, everything is growing away from you. Imagine putting a bunch of chocolate chips into your loaf of bread and tracking their emotion everywhere inside the loaf of bread, of course, except for the crust. You would see the chocolate chips moving away from you. So that's what we see. We see that the universe is expanding, not that it's exploding out from a tiny dot. And this expansion is actually really important to sort of the state of the universe as we know it, because when the universe began, we think it began very very smooth, like totally homogeneous. Everywhere was exactly like everywhere else. And why wouldn't it be right when the universe is created, why would you have one spot that's like denser than another spot. The problem is, however, a universe like that that's created perfectly smoothly. Nothing very interesting ever happens in that universe. There's nothing for gravity to do in that universe because there's no spots that are heavier or denser than anything else, which is what gravity needs to sort of like seed the structure to start coalescing things together into stars and play. And it's in galaxies and all that good stuff. So how did the universe get any structure? Well, it was perfectly smooth, except down to the quantum level. The quantum level, there are always random fluctuations. Every point in the universe gets a different random fluctuation, so you get these really super duper tiny little variations in the density of the universe due to quantum mechanics. And then inflation steps in. Inflation takes those tiny little quantum fluctuations and it blows them up to the macroscopic scale. It makes things which were invisibly small somehow suddenly now huge. Right, It takes a meter stick sized thing and it blows it up to a trillion light years. It takes something which was subatomic and it makes it macroscopic. So now those random quantum fluctuations are not small, they're pretty big and they're big enough to see the structure of the universe. So the reason that we have a galaxy over here and then over there it's empty space is because of a random quantum fluxual in the very early universe which was expanded out into something macroscopic that seeded the structure of that galaxy and allowed gravity to pull stuff together to make something interesting, to make me and to make you, and to make the sun that warms our toes. Now, the second part of Jeff's awesome question is that if the edges of the universe were expanding through nothing, what's slowing it down? Why isn't it still expanding at that crazy rate? So lots of really good angles on this question. First of all, we don't know if there is an edge to the universe. I think in his mind Jeff might be imagining in explosion, an explosion which has a wavefront which is moving through the universe and then slowing down. But we don't know that there was an edge. We don't know that there is an edge. I think the cleanest way to think about these things is to think that the universe is infinite. We don't know that's true, but it seems somehow more natural to have an infinite universe than to have an edge, and then you can grapple. Instead of thinking about the whole universe, just think about a chunk of it and think about sort of density of that part of the universe. So I imagine the whole universe created infinite at its birth as a very very dense place, and then expanded suddenly, very rapidly, using inflation. So there's no edge there. Everything is moving away from everything else. He also asks, if there's no edge, what's slowing it down? Why isn't it still expanding at that crazy rate? Awesome question. I wish I knew the answer. There was this incredible moment of inflation in the very early universe, this rapid expansion in a very short amount of time. We don't know what caused it. We have ideas about ideas, we sort of proto ideas for what might have caused it, crazy particles and fields called the infloton field, but those are sort of placeholders to have ideas. We don't really have any well worked out, super well formulated ideas that actually come together mathematically to explain inflation. So, because we don't know what started it and what sustained it. We also don't know why it stopped. We just know that it started, and we know that it's stopped, but the expansion itself has not stopped. It was very rapid in the very beginning, and then it was very slow for a while, But about five billion years ago it started to pick up again. Dark energy took over and it started to accelerate the expansion of the universe once again. And this expansion is very similar to what happened in the inflationary period of the universe. It's not nearly as rapid, but the sort of stretching of space is the same concept. We don't know if there's a relationship between the mechanism or the reason for why space is expanding now and why space expanded in the very beginning. We're pretty clueless about what dark energy is. Again. We have a few basic ideas for what might explain it, but none of them hold together mathematically, so most of this is just an observation. We see that this happened, we can't explain why. So it is still expanding a crazy rate, not as crazy, but we don't know the answer to the question why the universe stopped inflating and why it's not inflating at that crazy rate today. So Jess, the answer to your question is that the universe expanded so rapidly, not by things moving through space, but by expanding the nature of space itself, by creating new space between stuff. And why did that stop? We don't know why inflation itself stopped, but the expansion has not stopped. The universe is still expanding, and it's expanding faster and faster every day. All right, thanks for that super awesome question. I love all of these ideas. I have one more question I'm going to get to today, but first let's take another quick break. When you pop a piece of cheese into your mouth or enjoy a rich spoonful of Greek yogurt, you're probably not thinking about the environmental impact of each and every bite. But the people in the dairy industry are US. Dairy has set themselves some ambitious sustainability goals, including being greenhouse gas neutral by twenty to fifty. That's why they're working hard every day to find new ways to reduce waste, conserve natural resources, and drive down greenhouse gas emissions. Take water, for example, most dairy farms reuse water up to four times the same water, cools the milk, cleans equipment, washes the barn, and irrigates the crops. How is US Dairy tackling greenhouse gases? Many farms use anaerobic digestors that turn the methane from maneuver into renewable energy that can power farms, towns, and electric cars. So the next time you grab a slice of pizza or lick an ice cream cone, know that dairy farmers and processors around the country are using the latest practices and innovations to provide the nutrient dense dairy products we love with less of an impact. Visit us dairy dot com slash sustainability to learn more.

Thanks a lot, all right, Jeff from La who's basically an amateur cosmologist. Thank you for thinking deeply about the universe and for trying to reconcile what you've heard about the early days of the universe with what you understand about how the universe works. Again, that's exactly what doing physics means, so let's get to it. The first part of your question was if the universe expanded by a factor of ten to the thirty and ten to the minus thirty questions, how is that possible? Given that we know that there's a very hard limit on how fast things can move through space, which is the speed of light. It's a great question. Another way to think about this question is how did the universe get so big? I mean, the universe is about fourteen billion years old, but the size of the observable universe, the distance to the furthest things that we can see, you might expect to be fourteen billion years times the speed of light, which would be fourteen billion light years, but it's not. It's much much further than that. We can see things that are about forty five billion light years away, So the size of the observable universe is about ninety billion light years wide. How is that possible. How is it possible to see things which are further away then the speed of light times the age of the universe. How did that stuff get there so far? How did the universe expand faster than the speed of light? So it's a wonderful question. And the key concept you need to know to understand this is that there's a difference between moving through space and expansion of space. So moving through space is the kind of thing you're familiar with. You move through space every day when you get out of your bed and you go for a glass of water in the middle of the night, and you are moving through space. When you throw a baseball really really fast. When you get on your spaceship and you try to travel to a nearby star, you are moving through space. When you turn on your flashlight and you shine it at the moon, you are sending photons through space to the moon. And there is in fact, a very hard limit on the speed at which things can move through space, and that's the speed of light. In a vacuum, nothing, no information at all, can move through space faster than the speed of light. That includes neutrinos, that includes everything that include quantum information. It's a very tough rule, and breaking it would undermines special relativity, which we're pretty sure as an accurate description of space time in our universe. All right, so that's moving through space, but that's different from the expansion of space. The expansion of space means stretching space itself. So imagine, for example, you are one meter apart from your friend. You have a meter stick, and you measure exactly how far apart you are. You could take a step back. That would be moving through space. But you could also expand the space between you. You could take the very universe and stretch it so that now you guys are two meters apart without having moved through space at all. Right, Remember, space is not just the backdrop on which things happen. It's not the stage on which the acts of the universe are played out on. It's a dynamical thing. It's stretchy, it's like goo. It responds to the presence of mass and energy. It bends, it twists, it can expand, and it tells things how to move. So space is really part of the universe. It's not just like some fuzzy abstract concept, some set of glowing axes in our mind. That we just impose on the universe to try to make sense of it. Space really can do a bunch of weird things. You already know this because you know that gravity is not just a force, it's actually the curving of space. Right. The reason that the Earth goes around the Sun is not because gravity is a force which is tugging on it, but because the presence of the Sun changes the shape of space in its vicinity, so that an object moving in a straight up inertial path will move in a circle around the Sun. That's because space can bend and twist, changing the relative distances between things. So, for example, a photon a beam of light always takes the shortest path between two things. But the shortest path between two things isn't always what you imagine to be a straight line, because the shape of space can be complicated between two points the same way an airplane going from la to London takes the Great Circle route, right, which seems like a curve, is actually the shortest distance between two places on a curved surface, which is why gravity can influence even things that don't have mass. All right, So that tells us that space can do things, and it can stretch and it can expand. And so that's exactly what happened in the very early universe. It wasn't an explosion like a tiny dot of stuff and then everything exploded out from the center. Instead, it was an expansion of space itself. Huge amounts of new space were made everywhere all over the universe simultaneously. So that doesn't make it easier to understand. In fact, it makes it even more bind boggling that this happened, That every unit of space was blown up by a factor ten to the thirty in ten to the minus thirty seconds. It's an incredible moment in the history of the universe. It's an incredible idea to even have in your mind. Imagine coming up with this Bonker's notion and then realizing that actually it's the story that makes the most sense in the universe. And you might ask, well, how do we know, How do we know that the universe expanded in this way, that it didn't just explode from a tiny dot and spread out through the universe. Well, answer number one is that it would be impossible. As you say, it's not possible for things to travel that far in that short distance because of the limitation of the speed of light. It's against the rules. The only way to get things that far apart in that short amount of time is to create space between them, is to expand the space between everything. But it's more than that, because explosions and expansion look different. Explosions are like a bomb. You push everything out from one central location and send it flying in every direction, and if there is an explosion, you could look at the direction things are flying, you could track them backwards, and you could point back to the center. Right. If you come upon an explosion, you can look at the path of the debris and you can figure out where the bomb was. That's not true for an expansion. An expansion is more like a loaf of bread rising in the oven, where everything is growing at every point simultaneously, assuming you're not a terrible baker, right, and that your loaf is expanding smoothly. And that's what we see when we look out into the universe. We see these galaxies and they are rushing away from us. They are moving away from us, and they're moving away from us faster and faster every year. So either we are at the exact center of the universe by some incredible cosmic coincidence. There was an explosion and we happen to be right at the center of it. Or it looks this way because it's an expansion, and it would look this way at any point in the universe. See, the way an expansion looks is that it always looks like you're at the center of it, no matter where you are. And a loaf of bread, if you look around you, everything is growing away from you. Imagine putting a bunch of chocolate chips into your loaf of bread and tracking their emotion everywhere inside the loaf of bread, of course, except for the crust. You would see the chocolate chips moving away from you. So that's what we see. We see that the universe is expanding, not that it's exploding out from a tiny dot. And this expansion is actually really important to sort of the state of the universe as we know it, because when the universe began, we think it began very very smooth, like totally homogeneous. Everywhere was exactly like everywhere else. And why wouldn't it be right when the universe is created, why would you have one spot that's like denser than another spot. The problem is, however, a universe like that that's created perfectly smoothly. Nothing very interesting ever happens in that universe. There's nothing for gravity to do in that universe because there's no spots that are heavier or denser than anything else, which is what gravity needs to sort of like seed the structure to start coalescing things together into stars and play. And it's in galaxies and all that good stuff. So how did the universe get any structure? Well, it was perfectly smooth, except down to the quantum level. The quantum level, there are always random fluctuations. Every point in the universe gets a different random fluctuation, so you get these really super duper tiny little variations in the density of the universe due to quantum mechanics. And then inflation steps in. Inflation takes those tiny little quantum fluctuations and it blows them up to the macroscopic scale. It makes things which were invisibly small somehow suddenly now huge. Right, It takes a meter stick sized thing and it blows it up to a trillion light years. It takes something which was subatomic and it makes it macroscopic. So now those random quantum fluctuations are not small, they're pretty big and they're big enough to see the structure of the universe. So the reason that we have a galaxy over here and then over there it's empty space is because of a random quantum fluxual in the very early universe which was expanded out into something macroscopic that seeded the structure of that galaxy and allowed gravity to pull stuff together to make something interesting, to make me and to make you, and to make the sun that warms our toes. Now, the second part of Jeff's awesome question is that if the edges of the universe were expanding through nothing, what's slowing it down? Why isn't it still expanding at that crazy rate? So lots of really good angles on this question. First of all, we don't know if there is an edge to the universe. I think in his mind Jeff might be imagining in explosion, an explosion which has a wavefront which is moving through the universe and then slowing down. But we don't know that there was an edge. We don't know that there is an edge. I think the cleanest way to think about these things is to think that the universe is infinite. We don't know that's true, but it seems somehow more natural to have an infinite universe than to have an edge, and then you can grapple. Instead of thinking about the whole universe, just think about a chunk of it and think about sort of density of that part of the universe. So I imagine the whole universe created infinite at its birth as a very very dense place, and then expanded suddenly, very rapidly, using inflation. So there's no edge there. Everything is moving away from everything else. He also asks, if there's no edge, what's slowing it down? Why isn't it still expanding at that crazy rate? Awesome question. I wish I knew the answer. There was this incredible moment of inflation in the very early universe, this rapid expansion in a very short amount of time. We don't know what caused it. We have ideas about ideas, we sort of proto ideas for what might have caused it, crazy particles and fields called the infloton field, but those are sort of placeholders to have ideas. We don't really have any well worked out, super well formulated ideas that actually come together mathematically to explain inflation. So, because we don't know what started it and what sustained it. We also don't know why it stopped. We just know that it started, and we know that it's stopped, but the expansion itself has not stopped. It was very rapid in the very beginning, and then it was very slow for a while, But about five billion years ago it started to pick up again. Dark energy took over and it started to accelerate the expansion of the universe once again. And this expansion is very similar to what happened in the inflationary period of the universe. It's not nearly as rapid, but the sort of stretching of space is the same concept. We don't know if there's a relationship between the mechanism or the reason for why space is expanding now and why space expanded in the very beginning. We're pretty clueless about what dark energy is. Again. We have a few basic ideas for what might explain it, but none of them hold together mathematically, so most of this is just an observation. We see that this happened, we can't explain why. So it is still expanding a crazy rate, not as crazy, but we don't know the answer to the question why the universe stopped inflating and why it's not inflating at that crazy rate today. So Jess, the answer to your question is that the universe expanded so rapidly, not by things moving through space, but by expanding the nature of space itself, by creating new space between stuff. And why did that stop? We don't know why inflation itself stopped, but the expansion has not stopped. The universe is still expanding, and it's expanding faster and faster every day. All right, thanks for that super awesome question. I love all of these ideas. I have one more question I'm going to get to today, but first let's take another quick break. When you pop a piece of cheese into your mouth or enjoy a rich spoonful of Greek yogurt, you're probably not thinking about the environmental impact of each and every bite. But the people in the dairy industry are US. Dairy has set themselves some ambitious sustainability goals, including being greenhouse gas neutral by twenty to fifty. That's why they're working hard every day to find new ways to reduce waste, conserve natural resources, and drive down greenhouse gas emissions. Take water, for example, most dairy farms reuse water up to four times the same water, cools the milk, cleans equipment, washes the barn, and irrigates the crops. How is US Dairy tackling greenhouse gases? Many farms use anaerobic digestors that turn the methane from maneuver into renewable energy that can power farms, towns, and electric cars. So the next time you grab a slice of pizza or lick an ice cream cone, know that dairy farmers and processors around the country are using the latest practices and innovations to provide the nutrient dense dairy products we love with less of an impact. Visit us dairy dot com slash sustainability to learn more.

With the United Explorer Card, earn fifty thousand bonus miles, then head for places unseen and destinations unknown. Wherever your journey takes you, you'll enjoy remarkable rewards, including a free checked bag and two times the miles on every United purchase. You'll also receive two times the miles on dining and at hotels, so every experience is even more rewarding. Plus, when you fly United, you can look forward to United Club access with two United Club one time passes per year. Become a United Explorer Card member today and take off on more trips so you can take in once in a lifetime experiences everywhere you travel. Visit the explorercard dot com to apply today. Cards issued by JP Morgan Chase Bank NA Member FDIC subject to credit approval offer, subject to change. Terms apply.

With the United Explorer Card, earn fifty thousand bonus miles, then head for places unseen and destinations unknown. Wherever your journey takes you, you'll enjoy remarkable rewards, including a free checked bag and two times the miles on every United purchase. You'll also receive two times the miles on dining and at hotels, so every experience is even more rewarding. Plus, when you fly United, you can look forward to United Club access with two United Club one time passes per year. Become a United Explorer Card member today and take off on more trips so you can take in once in a lifetime experiences everywhere you travel. Visit the explorercard dot com to apply today. Cards issued by JP Morgan Chase Bank NA Member FDIC subject to credit approval offer, subject to change. Terms apply.

There are children, friends and families walking, riding on paths and roads every day. Remember they're real people with loved ones who need them to get home safely. Protect our cyclists and pedestrians because they're people too, Go safely. California from the California Office of Traffic Safety and Caltrans.

There are children, friends and families walking, riding on paths and roads every day. Remember they're real people with loved ones who need them to get home safely. Protect our cyclists and pedestrians because they're people too, Go safely. California from the California Office of Traffic Safety and Caltrans.

Okay, we're back and this is Daniel and I'm answering questions about the nature of the universe and how it expanded and whether it violates conservation of energy and our next question is a tiny bit more concrete.

Okay, we're back and this is Daniel and I'm answering questions about the nature of the universe and how it expanded and whether it violates conservation of energy and our next question is a tiny bit more concrete.

Hi, Daniel and Johi. I'm Tristan from Melbourne, Australia. Congratulations on the Oesome podcast. My question is about spice dust. We hear about it all the time, but what exactly is spice dust? Is it tiny gas molecules or really minute dust particles like here on Earth, or is spice dust just a relative term, and they're more like basketball sized or car sized or bigger.

Hi, Daniel and Johi. I'm Tristan from Melbourne, Australia. Congratulations on the Oesome podcast. My question is about spice dust. We hear about it all the time, but what exactly is spice dust? Is it tiny gas molecules or really minute dust particles like here on Earth, or is spice dust just a relative term, and they're more like basketball sized or car sized or bigger.

All right, thanks very much for that fun question. This is actually a surprisingly fascinating topic. When you think about dust, you think it's like dirt. It's something you want to get rid of. It's an annoyance. It gets in your way. If you zoom in on it, you discover that, like a lot of the dust in your house is actually left over dried bits of human skin that makes you want to throw up a little bit. So space dust is sort of similar. For a long time, people thought space dust was just like an annoyance. It was this stuff floating in space which like blocked your view. I mean, if you look out into space, it's incredible how far we can see. You are standing on the top of a rock in space and you're peering out in your eyeballs or absorbing photons that traveled billions of light years, mostly unimpeded to get to you. It's incredible that space is as clear as it is. So we shouldn't be complaining we have the best view in the universe. The kind of things we see with hubble are just eye dropping the gorgeous. But sometimes there are things that are obscured by space dust. If you look at the center of the galaxy, for example, they're huge clouds of dust that make it harder to see what's going on there. And for a long time, astronomers treated space dust that way like an annoyance, like, oh, these things are shrouded in dust, so we can't see them what's going on inside there? And if you're like me, your curiosity is only heightened when something is hidden. If something is behind a veil, like things inside a black hole, it just makes me want to know even more what's there. So for a long time space dust was treated that way. It's just something that gets in our way, something to be annoyed about. However, now we see that space dust is just sort of part of the dynamics of space, part of the astrophysical soup that's constantly churning, making new stars and all the crazy things, and it can actually help us understand the structure of the galaxies and how things work. For example, we can see space dust. It doesn't just block light, it actually gives off its own light. This is something I think is not widely enough understood. That everything in the universe glows, everything in the universe that's made out of our kind of stuff atoms. That's only five percent of the universe. But all that stuff glows, and it glows based on its temperature. The hotter you are, the more energetic photons you give off, which is why, for example, if you heat up metal, it starts to glow and it glows at different frequencies, different colors as it gets hotter. Everything is actually like that. Even you glow, and if you put on infrared goggles then you can see your body heat because of your temperature. But it's not just living things. Even rocks glow, even if they're very very they glow at some wavelength. And space dust is out there and it glows as well, so you can see it. It's not giving off visible light, but if you have a special camera like night vision goggles for the universe and what we call an infrared telescope, then you can see it. And if you point an infrared telescope, for example, at the Andromeda galaxy, you can see where in Andromeda there is this space dust. Because the space dust glows at different frequencies than the stars, the stars emit a visible light and you can see them. That's super fascinating. But then if you turn on your night vision goggles for space, you can see the other stuff, the colder stuff, which is glowing at longer wavelengths in the infrared, and you can see it totally differently. Andromeda looks different in the infrared. You can see where the space dust is, and that helps us understand like, how did androma form, what's going on over there, what are the dynamics, what things are moving against the other stuff. So these days space dust isn't just like an annoyance. It isn't just a cloud that gets in your way. It's another thing out there that we can study. And it turns out that there's a lot of different kinds of space dust. Most generally, what is space dust. It's basically anything that's out there in space that's very very small, right, So you wouldn't call Earth a big speck of space dust. This is one of those arbitrary categorizations in astronomy and astrophysics. Space dust is basically anything that's out there that's smaller than like a millimeter, and it can go down all the way to like a few molecules. But the upper edge is generally agreed to be like a millimeter or half a millimeter, maybe a tenth of a millimeter. Anything that size or smaller that's floating out in space, we call it space dust. Bigger than that, like a basketball or car sized thing, we would call that an asteroid or a comet, or even a proto planet or a moon or a sun if it gets big enough. So there's this whole spectrum of sizes of stuff in space, and things on the smaller edge call space dust. And you might wonder, like, well, why is there space dust? After all, you have these huge clouds of things formed after the Big Bang, and some of it gathered together to make stars, and some of it gathered together to make planets, but not everything instantly gets cleaned together. Right. Gravity is very patient, but it's also very very weak, and the gravity on very small objects, tiny little specks of stuff floating out in space, is very weak, and other things are much more powerful. One thing that prevents gravity from gathering stuff together is angular momentum. If something is moving in a circle around something with gravity, then it doesn't necessarily fall in the same way the Earth orbits the Sun without falling in even though there is gravity tugging on the Earth from the Sun. The reason we don't fall in immediately is because we're moving in a circle. The same reason the whole galaxy doesn't collapse into the central black hole is because of angular momentum. That's just one example, and so that keeps some space dust from collapsing into larger objects. And so you end up with this whole spectrum of really dense stuff that have sort of cleared out the space around them, then a whole distribution of smaller bits, which we call space dust, and we can study this stuff. NASA actually sends planes up into the high atmosphere to gather space dust and these big collectors under the wings to pull it together and say like, well, what's in there. And actually there's a huge amount of space dust out there. It's not very rare. The Earth is traveling through a cloud of this stuff. There's like one particle per million cubic meters, but there's a lot of cubic meters out there, and there's a lot of square meters on the surface of the Earth, and so a lot of space dust actually falls onto the Earth every year. Some of the stuff that's lying around your house might be dead bits of skin, but some of it might be space dust, because there are thousands of tons of space dust that reach the surface of the Earth every year. Yeah, fell out of my chair when I read that tidbit that fact. Thousands of tons of the stuff. If you could like sweep up all the space dust that hits the Earth and make a pile of it, it would be a huge, huge mountain of space dust. All right. So then what is this stuff? Right? What is this stuff that's out there that's floating through the universe that didn't get gathered together into planets and rocks and other kinds of stuff. Well, it's a big mix, right, It's basically a big soup of leftover stuff either from the very early universe that never got gathered together into something else, or that has had a chance to be part of a star or a planet and then got blown into little smithereens. So one category of stuff is stardust. Stardust are little pellets made on the outside of stars, the little grains, for example, of oxygen or carbon rich elements that are floating out near the outside of stars and that get blown out away from the star, so they get frozen into these little pellets. Remember that in the first population of stars, we had only hydrogen, but those hydrogen stars burned helium, and in later generations of stars fuse that helium into heavier and heavier stuff. So stars on the engines to make these heavier elements, and eventually they can gather together a lot of this We call it ash because it's the product of fusion. A lot of it falls to the center of the star, makes a denser and denser core, which eventually leads the star to collapse, but not all of it. Some of it gets blown out into the outer edges of the star, and then it can get pushed even further out and float out into space. So these little grains of stuff produced inside stars, this is called star dust, and this is floating out there, and a good amount of the space dust are actually these kinds of grains, and a lot of them came together to form our star and our planet. So a lot of what makes me and you and the Sun are actually these bits of other stars. Now, of course, inside the Earth and inside the Sun, they've all been melted down to their basic elements, and maybe you've infused into other stuff, but space dust hasn't. It's frozen. It's like a little time capsule that tells you where it came from. And if you can capture one of these grains of stardust and you can look at the relative fractions of stuff, like how much iron is there, how much carbon is there, then you can get an idea from what kind of star it came from. You can read like it's ancient history just by looking at what's inside of it. So each of these is like a little time capsule that tells us what happened. And these events are billions of years old. You know, the stardust grains that helped form our sun, well that was five billion years ago, so they were produced more than five billion years ago, and they're still floating around. Some of them coalesce into like micro meteorites, but they don't necessarily lose their elemental structure. They just sort of like get stuck together like a big pile of rice grains. And so if you're careful, you can tear them apart and look at the individual grains and still study these little time capsule from other stars. Now, sometimes you look at space doest capsules and you see something really strange, and people actually predicted that you would see this. You see things produced in supernovas. Supernova's, remember, are these very special occasions when a star's gravity overcomes its pressure and it collapses very very rapidly, this implosion, which then leads to an explosion where it throws crazy stuff through space. Well, in those moments of implosion are intense moments of fusion, and these are situations that allow for the creation of other kinds of elements and different mixtures of elements than what you would expect from the normal production you get in a star. And sometimes these things get thrown out during the supernova and they're like little time capsules, a little like samples from what's going on deep inside of supernova. So these supernova grains are super awesome vines because they're not created nearly as often, and there's this little time capsule from this incredible moment during one of the most violent acts in our universe. So they're super fun. And a lot of the other space dust is just floating tiny rocks. Basically. Some of them are carbonaceous, you know, other ones have iron or sulfur or nickel. Some of them are silicates, which means they're basically bits of sand, and they have all sorts of irregular shapes, you know, just like any random rocks. Some of them are kind of fluffy, little loose amalgams, some of them are very compact. Some of them accumulate little layers of ice around them, so you might expect them to be like super many comets. And the sizes of them differ. Right, they go all the way down from the tiny, tiny little grains up to you know, less than a millimeters or so, And this is important because the size determines how you can see them. Like pretty big grains actually reflect light, so if the sun is behind you, you could see them the way you see the moon like comes from the sun bounces off of them and then back to you. But if they're really really small, then they don't reflect light. They just sort of deflect it a little bit, which means it's only easy to see them if the light is behind them. They have to be back lit. And this is why, for example, we didn't really know that Jupiter had rings. It has rings made of dust until we got cameras out past Jupiter and you could look back and you could see those rings of dust back lit by the sun because they only deflect the light a little bit, so it's important how big they are, and it's also important their shape. We think this space dust is not just around the Solar System and not just in the galaxy, but also between the galaxies. It's basically spread out everywhere, and it's actually really valuable because these grains are not spheres. They're like weird oblong shapes. So what they do is they tend to align with magnetic fields. They're like tiny little needles and they tend to line up with magnetic fields. And people have been studying magnetic fields through space, wondering like, is their magnetic fields all through the galaxy? Are there magnetic fields between galaxies? Are there magnetic fields in deep space that were created during the Big Bang. This is called the primordial magnetic field. We have a whole podcast episode about it. If you listen to that, what you'll learn is that these dust grains line up with magnetic fields, which is important because it changes how light moves through it. Because these dust grains are now polarized, and so we can use space dust to sort of track the magnetic fields in otherwise empty portions of space, sort of like sprinkling magnetic filings on a sheet to see if there's a magnetic field there. It's actually good that space dust is sort of everywhere, because if space was truly empty, it would be much much harder to study it, all right, So I hope that answers your question. What is space dust? It's tiny little grains of stuff. Some of them create within stars, some within supernovas, some of them aligning with magnetic fields to tell us where things are. We don't know what their future is. Maybe one day some of them will gather together to make a new star, a new planet, even a new race of intelligent aliens that make a podcast even better than ours. All right, So thank you very much everybody who's sent in questions, and thanks also to those of you who have sent in listener questions audio and not yet had your questions answer. I promise we will get through our backlog and we will answer all of your questions, because I think that everybody out there should be asking questions about the universe, should be tapped into their innate curiosity discovering how the world works. Asking these questions and knowing that there's an answer is one of the most satisfying experiences. It tells you that maybe the human mind is capable of gaining not a full understanding, but at least a foothold into our universe of ignorance, cracking that open a little bit and revealing a tiny slice of how the universe works. It's certainly we're doing, even if it doesn't immediately lead to applications and better lasers and pants with better zippers and stuff like that. I view the deep exploration of the nature in the universe to be on par with the creation of art. It's part of what makes life worth living. So thanks everyone for lending us your questions and your curiosity. It's been a wonderful ride, and tune in next time for more questions from listeners. Thanks for listening, and remember that Daniel and Jorge Explain the Universe is a production of iHeartRadio. 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